Follicle-stellate cells are pituitary non-granular cells that are arranged between secretory cells or organized in follicles with small lumens. Cells from the follicles exhibit the typical phenotype of a transporting epithelium, including apical microvilli with a cilium and tight junctions. Freeze-fracture electron microscopy images show that the tight junctions consist of 5-7 anastomosing strands and that cultured follicle-stellate cells develop a trans-epithelial electrical resistance characteristic of "tight" epithelia. Here, we investigate the molecular composition of the tight junction from follicle stellate cells. We found that the rat anterior pituitary lobe expresses mRNAs for claudins 2, 4 and 5; the proteins of all these claudins are observed in the anterior lobe, whereas the intermediate lobe expresses claudins 2 and 5 and the posterior lobe contains only claudin 5. Follicle-stellate cells, identified by their protein marker S100β, expresses claudin 4 in the apical membrane, in co-localization with dipeptidyl-peptidase and near acetylated β-tubulin. Claudin 4 partially co-localizes with E-cadherin, indicating that a fraction of the protein is located in the basolateral domain. Follicle-stellate-enriched cell cultures develop patches of polygonal cells expressing claudin 4 and E-cadherin, encircled by extensive monolayers of fusiform cells. Claudin 2 stains specifically blood vessels, identified by claudin 5 and VE-cadherin labels. Thus, follicles in the anterior pituitary consist of "tight" epithelia that can carry out intense vectorial transport, together with a high cation movement in blood vessels, possibly related to the ion requirements of excitable secretory cells for hormone secretion.
The development of the scanning electron microscope (SEM) has added increasing knowledge to the structure of the various organs, giving us a new dimension to the study of their constituents. Although there are few studies on cardiac tissue using the SEM, these are mainly oriented to describe the myocardial cytoplasmic elements and the myocardial cell surface.Interested in our laboratory in cardiac microcirculation, one of the studies in progress is the openning of the arterioluminal and Thebesian vessels into the cardiac cavities. In the present communication we describe the endocardial surface of the right atrium in mice with particular emphasys on the foraminula of vessels openning into the atrium by using the scanning electron microscope.Right atria from mice were fixed immediately after death in 2.5% cacodylate buffered-glutaraldehyde, pH 7.4 for 3 hrs at 4°C and dehydrated in a graded series of acetone.
In humans, the pituitary gland is covered by a fibrous capsule and is considered a continuation of the meningeal sheath. However, in rodents some studies concluded that only the pars tuberalis (PT) and pars nervosa (PN) are enwrapped by the pia mater, while others showed that the whole gland is covered by this sheath. At PT the median eminence subarachnoid drains cerebrospinal fluid (CSF) to its cisternal system representing a pathway to the hypothalamus. In the present study we examined the rat pituitary capsule to elucidate its configuration, its physical interaction with the pituitary border and its relationship with the CSF. Furthermore, we also revisited the histology of the pituitary cleft and looked whether CSF drained in it. To answer such questions, we used scanning and transmission electron microscopy, intracerebroventricular infusion of Evan´s blue, fluorescent beads, and sodium fluorescein. The latter was measured in the pars distalis (PD) and various intracranial tissues. We found a pituitary capsule resembling leptomeninges, thick at the dorsal side of the pars intermedia (PI) and PD, thicker at the level of PI in contiguity with the PN and thinner at the rostro-ventral side as a thin membrane of fibroblast-like cells embedded in a fibrous layer. The capsule has abundant capillaries on all sides. Our results showed that the CSFs bathe between the capsule and the surface of the whole gland, and ciliate cells are present in the pituitary border. Our data suggest that the pituitary gland intercommunicates with the central nervous system (CNS) through the CSF.
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